The origins of respiratory disease, such as asthma in childhood and COPD in later life are unclear. Maternal smoking during pregnancy and low birth weight is associated with increased risk of asthma, poor lung function in adults and COPD in old age. Exposure to oxidative stress and poor nutrition in utero is thought to cause damage to the lung and alter the normal course of lung development. Glutathione S-transferases (GST) are potent antioxidants. In this work, genetic polymorphisms that alter GST enzyme activity were genotyped in a family-based childhood asthma cohort (341 families, n = 1508) and analysed to investigate whether they alter the risk of developing asthma when individuals are exposed to environmental tobacco smoke. Real-time PCR based copy number variation methodology was developed to genotype the common gene deletion polymorphism of GSTT1 and GSTM1 genes, for other GST genes (GSTP1 and GSTO2) SNP haplotypes were constructed. A rare GSTO2 haplotype was negatively associated with asthma susceptibility, atopy severity, and FEV1 values. Asthmatic children with a GSTT1 gene deletion, or a common GSTP1 haplotype, developed more severe asthma compared to individuals with a GSTT1 gene or non-carriers of the GSTP1 haplotype. Total IgE levels were increased in GSTT1*0 individuals when exposed to tobacco smoke in early life, suggesting a gene-environment interaction. GSTO2 may be a shared susceptibility locus for asthma in childhood and COPD in later life. Animal models of maternal protein-restriction during pregnancy can induce hypertension, diabetes and endothelial dysfunction in offspring and in some of these models alterations to lung gene expression and lung architecture have been reported. This work established that a rat model of maternal dietary protein-restriction during pregnancy known to induce hypertension in the offspring, results in persistent alterations to the expression of genes in the lungs of adult offspring (120 days), including genes involved in glucocorticoid action (Hsd11b2), growth (Igf1 & 2 and Pcdh1) and alveolar development (Tp53). Lung microRNA expression profiles were also altered in response to exposure to protein restriction in utero. These findings suggest a role for nutritional programming in respiratory disease susceptibility in later life and a role for microRNAs in the study of the developmental origins of health and disease in general. Further work will include the investigation of epigenetic mechanisms that control nutritional programming in lungs of animals exposed to protein-restriction in utero. This work has demonstrated that GST polymorphism is a risk factor for childhood asthma and certain genotypes can offer some protection against the development of severe asthma. There was little evidence to suggest that GST polymorphism modulates the effects of smoke exposure in early life. In addition, we have demonstrated that maternal diets that are poor in nutrition could predispose her offspring to respiratory disease in later life by altering the course of normal lung development in early life or response to environmental stimuli in later life.
| Identifer | oai:union.ndltd.org:bl.uk/oai:ethos.bl.uk:523207 |
| Date | January 2010 |
| Creators | Rose-Zerilli, Matthew J. J. |
| Contributors | Holloway, John |
| Publisher | University of Southampton |
| Source Sets | Ethos UK |
| Detected Language | English |
| Type | Electronic Thesis or Dissertation |
| Source | https://eprints.soton.ac.uk/159853/ |
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